path: root/docs/model-api.txt

===============
Model reference
===============

A model is the single, definitive source of data about your data. It contains
the essential fields and behaviors of the data you're storing. Generally, each
model maps to a single database table.

The basics:

    * Each model is a Python class that subclasses ``django.db.models.Model``.
    * Each attribute of the model represents a database field.
    * Model metadata (non-field information) goes in an inner class named
      ``Meta``.
    * Metadata used for Django's admin site goes into an inner class named
      ``Admin``.
    * With all of this, Django gives you an automatically-generated
      database-access API, which is explained in the `Database API reference`_.

A companion to this document is the `official repository of model examples`_.
(In the Django source distribution, these examples are in the
``tests/modeltests`` directory.)

.. _Database API reference: ../db-api/
.. _official repository of model examples: ../models/

Quick example
=============

This example model defines a ``Person``, which has a ``first_name`` and
``last_name``::

    from django.db import models

    class Person(models.Model):
        first_name = models.CharField(max_length=30)
        last_name = models.CharField(max_length=30)

``first_name`` and ``last_name`` are *fields* of the model. Each field is
specified as a class attribute, and each attribute maps to a database column.

The above ``Person`` model would create a database table like this::

    CREATE TABLE myapp_person (
        "id" serial NOT NULL PRIMARY KEY,
        "first_name" varchar(30) NOT NULL,
        "last_name" varchar(30) NOT NULL
    );

Some technical notes:

    * The name of the table, ``myapp_person``, is automatically derived from
      some model metadata but can be overridden. See `Table names`_ below.
    * An ``id`` field is added automatically, but this behavior can be
      overridden. See `Automatic primary key fields`_ below.
    * The ``CREATE TABLE`` SQL in this example is formatted using PostgreSQL
      syntax, but it's worth noting Django uses SQL tailored to the database
      backend specified in your `settings file`_.

.. _settings file: ../settings/

Fields
======

The most important part of a model -- and the only required part of a model --
is the list of database fields it defines. Fields are specified by class
attributes.

Example::

    class Musician(models.Model):
        first_name = models.CharField(max_length=50)
        last_name = models.CharField(max_length=50)
        instrument = models.CharField(max_length=100)

    class Album(models.Model):
        artist = models.ForeignKey(Musician)
        name = models.CharField(max_length=100)
        release_date = models.DateField()
        num_stars = models.IntegerField()

Field name restrictions
-----------------------

Django places only two restrictions on model field names:

    1. A field name cannot be a Python reserved word, because that would result
       in a Python syntax error. For example::

           class Example(models.Model):
               pass = models.IntegerField() # 'pass' is a reserved word!

    2. A field name cannot contain more than one underscore in a row, due to
       the way Django's query lookup syntax works. For example::

           class Example(models.Model):
               foo__bar = models.IntegerField() # 'foo__bar' has two underscores!

These limitations can be worked around, though, because your field name doesn't
necessarily have to match your database column name. See `db_column`_ below.

SQL reserved words, such as ``join``, ``where`` or ``select``, *are* allowed as
model field names, because Django escapes all database table names and column
names in every underlying SQL query. It uses the quoting syntax of your
particular database engine.

Field types
-----------

Each field in your model should be an instance of the appropriate ``Field``
class. Django uses the field class types to determine a few things:

    * The database column type (e.g. ``INTEGER``, ``VARCHAR``).
    * The widget to use in Django's admin interface, if you care to use it
      (e.g. ``<input type="text">``, ``<select>``).
    * The minimal validation requirements, used in Django's admin and in
      manipulators.

Here are all available field types:

``AutoField``
~~~~~~~~~~~~~

An ``IntegerField`` that automatically increments according to available IDs.
You usually won't need to use this directly; a primary key field will
automatically be added to your model if you don't specify otherwise. See
`Automatic primary key fields`_.

``BooleanField``
~~~~~~~~~~~~~~~~

A true/false field.

The admin represents this as a checkbox.

``CharField``
~~~~~~~~~~~~~

A string field, for small- to large-sized strings.

For large amounts of text, use ``TextField``.

The admin represents this as an ``<input type="text">`` (a single-line input).

``CharField`` has an extra required argument, ``max_length``, the maximum length
(in characters) of the field. The max_length is enforced at the database level
and in Django's validation.

Django veterans: Note that the argument is now called ``max_length`` to
provide consistency throughout Django. There is full legacy support for
the old ``maxlength`` argument, but ``max_length`` is preferred.

``CommaSeparatedIntegerField``
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

A field of integers separated by commas. As in ``CharField``, the ``max_length``
argument is required.

``DateField``
~~~~~~~~~~~~~

A date field. Has a few extra optional arguments:

    ======================  ===================================================
    Argument                Description
    ======================  ===================================================
    ``auto_now``            Automatically set the field to now every time the
                            object is saved. Useful for "last-modified"
                            timestamps. Note that the current date is *always*
                            used; it's not just a default value that you can
                            override.

    ``auto_now_add``        Automatically set the field to now when the object
                            is first created. Useful for creation of
                            timestamps. Note that the current date is *always*
                            used; it's not just a default value that you can
                            override.
    ======================  ===================================================

The admin represents this as an ``<input type="text">`` with a JavaScript
calendar, and a shortcut for "Today."  The JavaScript calendar will always start
the week on a Sunday.

``DateTimeField``
~~~~~~~~~~~~~~~~~

A date and time field. Takes the same extra options as ``DateField``.

The admin represents this as two ``<input type="text">`` fields, with
JavaScript shortcuts.

``DecimalField``
~~~~~~~~~~~~~~~~

**New in Django development version**

A fixed-precision decimal number, represented in Python by a ``Decimal`` instance.
Has two **required** arguments:

    ======================  ===================================================
    Argument                Description
    ======================  ===================================================
    ``max_digits``          The maximum number of digits allowed in the number.

    ``decimal_places``      The number of decimal places to store with the
                            number.
    ======================  ===================================================

For example, to store numbers up to 999 with a resolution of 2 decimal places,
you'd use::

    models.DecimalField(..., max_digits=5, decimal_places=2)

And to store numbers up to approximately one billion with a resolution of 10
decimal places::

    models.DecimalField(..., max_digits=19, decimal_places=10)

The admin represents this as an ``<input type="text">`` (a single-line input).

``EmailField``
~~~~~~~~~~~~~~

A ``CharField`` that checks that the value is a valid e-mail address.

In Django 0.96, this doesn't accept ``max_length``; its ``max_length`` is
automatically set to 75. In the Django development version, ``max_length`` is
set to 75 by default, but you can specify it to override default behavior.

``FileField``
~~~~~~~~~~~~~

A file-upload field. Has one **required** argument:

    ======================  ===================================================
    Argument                Description
    ======================  ===================================================
    ``upload_to``           A local filesystem path that will be appended to
                            your ``MEDIA_ROOT`` setting to determine the
                            output of the ``get_<fieldname>_url()`` helper
                            function.
    ======================  ===================================================

This path may contain `strftime formatting`_, which will be replaced by the
date/time of the file upload (so that uploaded files don't fill up the given
directory).

The admin represents this field as an ``<input type="file">`` (a file-upload
widget).

Using a ``FileField`` or an ``ImageField`` (see below) in a model takes a few
steps:

    1. In your settings file, you'll need to define ``MEDIA_ROOT`` as the
       full path to a directory where you'd like Django to store uploaded
       files. (For performance, these files are not stored in the database.)
       Define ``MEDIA_URL`` as the base public URL of that directory. Make
       sure that this directory is writable by the Web server's user
       account.

    2. Add the ``FileField`` or ``ImageField`` to your model, making sure
       to define the ``upload_to`` option to tell Django to which
       subdirectory of ``MEDIA_ROOT`` it should upload files.

    3. All that will be stored in your database is a path to the file
       (relative to ``MEDIA_ROOT``). You'll most likely want to use the
       convenience ``get_<fieldname>_url`` function provided by Django. For
       example, if your ``ImageField`` is called ``mug_shot``, you can get
       the absolute URL to your image in a template with ``{{
       object.get_mug_shot_url }}``.

For example, say your ``MEDIA_ROOT`` is set to ``'/home/media'``, and
``upload_to`` is set to ``'photos/%Y/%m/%d'``. The ``'%Y/%m/%d'`` part of
``upload_to`` is strftime formatting; ``'%Y'`` is the four-digit year,
``'%m'`` is the two-digit month and ``'%d'`` is the two-digit day. If you
upload a file on Jan. 15, 2007, it will be saved in the directory
``/home/media/photos/2007/01/15``.

If you want to retrieve the upload file's on-disk filename, or a URL that
refers to that file, or the file's size, you can use the
``get_FOO_filename()``, ``get_FOO_url()`` and ``get_FOO_size()`` methods.
They are all documented here__.

__ ../db-api/#get-foo-filename

Note that whenever you deal with uploaded files, you should pay close attention
to where you're uploading them and what type of files they are, to avoid
security holes. *Validate all uploaded files* so that you're sure the files are
what you think they are. For example, if you blindly let somebody upload files,
without validation, to a directory that's within your Web server's document
root, then somebody could upload a CGI or PHP script and execute that script by
visiting its URL on your site. Don't allow that.

.. _`strftime formatting`: http://docs.python.org/lib/module-time.html#l2h-1941

**New in development version:**  By default, ``FileField`` instances are
created as ``varchar(100)`` columns in your database. As with other fields, you
can change the maximum length using the ``max_length`` argument.

``FilePathField``
~~~~~~~~~~~~~~~~~

A field whose choices are limited to the filenames in a certain directory
on the filesystem. Has three special arguments, of which the first is
**required**:

    ======================  ===================================================
    Argument                Description
    ======================  ===================================================
    ``path``                Required. The absolute filesystem path to a
                            directory from which this ``FilePathField`` should
                            get its choices. Example: ``"/home/images"``.

    ``match``               Optional. A regular expression, as a string, that
                            ``FilePathField`` will use to filter filenames.
                            Note that the regex will be applied to the
                            base filename, not the full path. Example:
                            ``"foo.*\.txt$"``, which will match a file called
                            ``foo23.txt`` but not ``bar.txt`` or ``foo23.gif``.

    ``recursive``           Optional. Either ``True`` or ``False``. Default is
                            ``False``. Specifies whether all subdirectories of
                            ``path`` should be included.
    ======================  ===================================================

Of course, these arguments can be used together.

The one potential gotcha is that ``match`` applies to the base filename,
not the full path. So, this example::

    FilePathField(path="/home/images", match="foo.*", recursive=True)

...will match ``/home/images/foo.gif`` but not ``/home/images/foo/bar.gif``
because the ``match`` applies to the base filename (``foo.gif`` and
``bar.gif``).

**New in development version:**  By default, ``FilePathField`` instances are
created as ``varchar(100)`` columns in your database. As with other fields, you
can change the maximum length using the ``max_length`` argument.

``FloatField``
~~~~~~~~~~~~~~

**Changed in Django development version**

A floating-point number represented in Python by a ``float`` instance.

The admin represents this as an ``<input type="text">`` (a single-line input).

**NOTE:** The semantics of ``FloatField`` have changed in the Django
development version. See the `Django 0.96 documentation`_ for the old behavior.

.. _Django 0.96 documentation: http://www.djangoproject.com/documentation/0.96/model-api/#floatfield

``ImageField``
~~~~~~~~~~~~~~

Like `FileField`_, but validates that the uploaded object is a valid
image. Has two extra optional arguments, ``height_field`` and
``width_field``, which, if set, will be auto-populated with the height and
width of the image each time a model instance is saved.

In addition to the special ``get_FOO_*`` methods that are available for
``FileField``, an ``ImageField`` also has ``get_FOO_height()`` and
``get_FOO_width()`` methods. These are documented elsewhere_.

Requires the `Python Imaging Library`_.

.. _Python Imaging Library: http://www.pythonware.com/products/pil/
.. _elsewhere: ../db-api/#get-foo-height-and-get-foo-width

**New in development version:**  By default, ``ImageField`` instances are
created as ``varchar(100)`` columns in your database. As with other fields, you
can change the maximum length using the ``max_length`` argument.


``IntegerField``
~~~~~~~~~~~~~~~~

An integer.

The admin represents this as an ``<input type="text">`` (a single-line input).

``IPAddressField``
~~~~~~~~~~~~~~~~~~

An IP address, in string format (e.g. "192.0.2.30").

The admin represents this as an ``<input type="text">`` (a single-line input).

``NullBooleanField``
~~~~~~~~~~~~~~~~~~~~

Like a ``BooleanField``, but allows ``NULL`` as one of the options.  Use this
instead of a ``BooleanField`` with ``null=True``.

The admin represents this as a ``<select>`` box with "Unknown", "Yes" and "No" choices.

``PhoneNumberField``
~~~~~~~~~~~~~~~~~~~~

A ``CharField`` that checks that the value is a valid U.S.A.-style phone
number (in the format ``XXX-XXX-XXXX``).

``PositiveIntegerField``
~~~~~~~~~~~~~~~~~~~~~~~~

Like an ``IntegerField``, but must be positive.

``PositiveSmallIntegerField``
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

Like a ``PositiveIntegerField``, but only allows values under a certain
(database-dependent) point.

``SlugField``
~~~~~~~~~~~~~

"Slug" is a newspaper term. A slug is a short label for something,
containing only letters, numbers, underscores or hyphens. They're generally
used in URLs.

Like a CharField, you can specify ``max_length``. If ``max_length`` is
not specified, Django will use a default length of 50.

Implies ``db_index=True``.

Accepts an extra option, ``prepopulate_from``, which is a list of fields
from which to auto-populate the slug, via JavaScript, in the object's admin
form::

    models.SlugField(prepopulate_from=("pre_name", "name"))

``prepopulate_from`` doesn't accept DateTimeFields, ForeignKeys nor
ManyToManyFields.

The admin represents ``SlugField`` as an ``<input type="text">`` (a
single-line input).

``SmallIntegerField``
~~~~~~~~~~~~~~~~~~~~~

Like an ``IntegerField``, but only allows values under a certain
(database-dependent) point.

``TextField``
~~~~~~~~~~~~~

A large text field.

The admin represents this as a ``<textarea>`` (a multi-line input).

``TimeField``
~~~~~~~~~~~~~

A time. Accepts the same auto-population options as ``DateField`` and
``DateTimeField``.

The admin represents this as an ``<input type="text">`` with some
JavaScript shortcuts.

``URLField``
~~~~~~~~~~~~

A field for a URL. If the ``verify_exists`` option is ``True`` (default),
the URL given will be checked for existence (i.e., the URL actually loads
and doesn't give a 404 response).

The admin represents this as an ``<input type="text">`` (a single-line input).

``URLField`` takes an optional argument, ``max_length``, the maximum length (in
characters) of the field. The maximum length is enforced at the database level and
in Django's validation. If you don't specify ``max_length``, a default of 200
is used.

``USStateField``
~~~~~~~~~~~~~~~~

A two-letter U.S. state abbreviation.

The admin represents this as an ``<input type="text">`` (a single-line input).

``XMLField``
~~~~~~~~~~~~

A ``TextField`` that checks that the value is valid XML that matches a
given schema. Takes one required argument, ``schema_path``, which is the
filesystem path to a RelaxNG_ schema against which to validate the field.

.. _RelaxNG: http://www.relaxng.org/

Field options
-------------

The following arguments are available to all field types. All are optional.

``null``
~~~~~~~~

If ``True``, Django will store empty values as ``NULL`` in the database.
Default is ``False``.

Note that empty string values will always get stored as empty strings, not
as ``NULL``. Only use ``null=True`` for non-string fields such as integers,
booleans and dates. For both types of fields, you will also need to set
``blank=True`` if you wish to permit empty values in forms, as the ``null``
parameter only affects database storage (see blank_, below).

Avoid using ``null`` on string-based fields such as ``CharField`` and
``TextField`` unless you have an excellent reason. If a string-based field
has ``null=True``, that means it has two possible values for "no data":
``NULL``, and the empty string. In most cases, it's redundant to have two
possible values for "no data;" Django convention is to use the empty
string, not ``NULL``.

.. note::
    When using the Oracle database backend, the ``null=True`` option will
    be coerced for string-based fields that can blank, and the value
    ``NULL`` will be stored to denote the empty string.

``blank``
~~~~~~~~~

If ``True``, the field is allowed to be blank. Default is ``False``.

Note that this is different than ``null``. ``null`` is purely
database-related, whereas ``blank`` is validation-related. If a field has
``blank=True``, validation on Django's admin site will allow entry of an
empty value. If a field has ``blank=False``, the field will be required.

``choices``
~~~~~~~~~~~

An iterable (e.g., a list or tuple) of 2-tuples to use as choices for this
field.

If this is given, Django's admin will use a select box instead of the
standard text field and will limit choices to the choices given.

A choices list looks like this::

    YEAR_IN_SCHOOL_CHOICES = (
        ('FR', 'Freshman'),
        ('SO', 'Sophomore'),
        ('JR', 'Junior'),
        ('SR', 'Senior'),
        ('GR', 'Graduate'),
    )

The first element in each tuple is the actual value to be stored. The
second element is the human-readable name for the option.

The choices list can be defined either as part of your model class::

    class Foo(models.Model):
        GENDER_CHOICES = (
            ('M', 'Male'),
            ('F', 'Female'),
        )
        gender = models.CharField(max_length=1, choices=GENDER_CHOICES)

or outside your model class altogether::

    GENDER_CHOICES = (
        ('M', 'Male'),
        ('F', 'Female'),
    )
    class Foo(models.Model):
        gender = models.CharField(max_length=1, choices=GENDER_CHOICES)

For each model field that has ``choices`` set, Django will add a method to
retrieve the human-readable name for the field's current value. See
`get_FOO_display`_ in the database API documentation.

.. _get_FOO_display: ../db-api/#get-foo-display

Finally, note that choices can be any iterable object -- not necessarily a
list or tuple. This lets you construct choices dynamically. But if you find
yourself hacking ``choices`` to be dynamic, you're probably better off using
a proper database table with a ``ForeignKey``. ``choices`` is meant for static
data that doesn't change much, if ever.

``core``
~~~~~~~~

For objects that are edited inline to a related object.

In the Django admin, if all "core" fields in an inline-edited object are
cleared, the object will be deleted.

It is an error to have an inline-editable relation without at least one
``core=True`` field.

Please note that each field marked "core" is treated as a required field by the
Django admin site. Essentially, this means you should put ``core=True`` on all
required fields in your related object that is being edited inline.

``db_column``
~~~~~~~~~~~~~

The name of the database column to use for this field. If this isn't given,
Django will use the field's name.

If your database column name is an SQL reserved word, or contains
characters that aren't allowed in Python variable names -- notably, the
hyphen -- that's OK. Django quotes column and table names behind the
scenes.

``db_index``
~~~~~~~~~~~~

If ``True``, ``django-admin.py sqlindexes`` will output a ``CREATE INDEX``
statement for this field.

``db_tablespace``
~~~~~~~~~~~~~~~~~

**New in Django development version**

The name of the database tablespace to use for this field's index, if
this field is indexed. The default is the project's
``DEFAULT_INDEX_TABLESPACE`` setting, if set, or the ``db_tablespace``
of the model, if any. If the backend doesn't support tablespaces, this
option is ignored.

``default``
~~~~~~~~~~~

The default value for the field. This can be a value or a callable object. If
callable it will be called every time a new object is created.

``editable``
~~~~~~~~~~~~

If ``False``, the field will not be editable in the admin or via form
processing using the object's ``AddManipulator`` or ``ChangeManipulator``
classes. Default is ``True``.

``help_text``
~~~~~~~~~~~~~

Extra "help" text to be displayed under the field on the object's admin
form. It's useful for documentation even if your object doesn't have an
admin form.

Note that this value is *not* HTML-escaped when it's displayed in the admin
interface. This lets you include HTML in ``help_text`` if you so desire. For
example::

	help_text="Please use the following format: <em>YYYY-MM-DD</em>."

``primary_key``
~~~~~~~~~~~~~~~

If ``True``, this field is the primary key for the model.

If you don't specify ``primary_key=True`` for any fields in your model,
Django will automatically add this field::

    id = models.AutoField('ID', primary_key=True)

Thus, you don't need to set ``primary_key=True`` on any of your fields
unless you want to override the default primary-key behavior.

``primary_key=True`` implies ``null=False`` and ``unique=True``. Only
one primary key is allowed on an object.

``radio_admin``
~~~~~~~~~~~~~~~

By default, Django's admin uses a select-box interface (<select>) for
fields that are ``ForeignKey`` or have ``choices`` set. If ``radio_admin``
is set to ``True``, Django will use a radio-button interface instead.

Don't use this for a field unless it's a ``ForeignKey`` or has ``choices``
set.

``unique``
~~~~~~~~~~

If ``True``, this field must be unique throughout the table.

This is enforced at the database level and at the Django admin-form level. If
you try to save a model with a duplicate value in a ``unique`` field, a
``django.db.IntegrityError`` will be raised by the model's ``save()`` method.

``unique_for_date``
~~~~~~~~~~~~~~~~~~~

Set this to the name of a ``DateField`` or ``DateTimeField`` to require
that this field be unique for the value of the date field.

For example, if you have a field ``title`` that has
``unique_for_date="pub_date"``, then Django wouldn't allow the entry of
two records with the same ``title`` and ``pub_date``.

This is enforced at the Django admin-form level but not at the database level.

``unique_for_month``
~~~~~~~~~~~~~~~~~~~~

Like ``unique_for_date``, but requires the field to be unique with respect
to the month.

``unique_for_year``
~~~~~~~~~~~~~~~~~~~

Like ``unique_for_date`` and ``unique_for_month``.

``validator_list``
~~~~~~~~~~~~~~~~~~

A list of extra validators to apply to the field. Each should be a callable
that takes the parameters ``field_data, all_data`` and raises
``django.core.validators.ValidationError`` for errors. (See the
`validator docs`_.)

Django comes with quite a few validators. They're in ``django.core.validators``.

.. _validator docs: ../forms/#validators

Verbose field names
-------------------

Each field type, except for ``ForeignKey``, ``ManyToManyField`` and
``OneToOneField``, takes an optional first positional argument -- a
verbose name. If the verbose name isn't given, Django will automatically create
it using the field's attribute name, converting underscores to spaces.

In this example, the verbose name is ``"Person's first name"``::

    first_name = models.CharField("Person's first name", max_length=30)

In this example, the verbose name is ``"first name"``::

    first_name = models.CharField(max_length=30)

``ForeignKey``, ``ManyToManyField`` and ``OneToOneField`` require the first
argument to be a model class, so use the ``verbose_name`` keyword argument::

    poll = models.ForeignKey(Poll, verbose_name="the related poll")
    sites = models.ManyToManyField(Site, verbose_name="list of sites")
    place = models.OneToOneField(Place, verbose_name="related place")

Convention is not to capitalize the first letter of the ``verbose_name``.
Django will automatically capitalize the first letter where it needs to.

Relationships
-------------

Clearly, the power of relational databases lies in relating tables to each
other. Django offers ways to define the three most common types of database
relationships: Many-to-one, many-to-many and one-to-one.

Many-to-one relationships
~~~~~~~~~~~~~~~~~~~~~~~~~

To define a many-to-one relationship, use ``ForeignKey``. You use it just like
any other ``Field`` type: by including it as a class attribute of your model.

``ForeignKey`` requires a positional argument: the class to which the model is
related.

For example, if a ``Car`` model has a ``Manufacturer`` -- that is, a
``Manufacturer`` makes multiple cars but each ``Car`` only has one
``Manufacturer`` -- use the following definitions::

    class Manufacturer(models.Model):
        # ...

    class Car(models.Model):
        manufacturer = models.ForeignKey(Manufacturer)
        # ...

To create a recursive relationship -- an object that has a many-to-one
relationship with itself -- use ``models.ForeignKey('self')``.

If you need to create a relationship on a model that has not yet been defined,
you can use the name of the model, rather than the model object itself::

    class Car(models.Model):
        manufacturer = models.ForeignKey('Manufacturer')
        # ...

    class Manufacturer(models.Model):
        # ...

Note, however, that this only refers to models in the same models.py file -- you
cannot use a string to reference a model defined in another application or
imported from elsewhere.

**New in Django development version:** To refer to models defined in another
application, you must instead explicitly specify the application label. For
example, if the ``Manufacturer`` model above is defined in another application
called ``production``, you'd need to use::

    class Car(models.Model):
        manufacturer = models.ForeignKey('production.Manufacturer')

Behind the scenes, Django appends ``"_id"`` to the field name to create its
database column name. In the above example, the database table for the ``Car``
model will have a ``manufacturer_id`` column. (You can change this explicitly
by specifying ``db_column``; see ``db_column`` below.)  However, your code
should never have to deal with the database column name, unless you write
custom SQL. You'll always deal with the field names of your model object.

It's suggested, but not required, that the name of a ``ForeignKey`` field
(``manufacturer`` in the example above) be the name of the model, lowercase.
You can, of course, call the field whatever you want. For example::

    class Car(models.Model):
        company_that_makes_it = models.ForeignKey(Manufacturer)
        # ...

See the `Many-to-one relationship model example`_ for a full example.

.. _Many-to-one relationship model example: ../models/many_to_one/

``ForeignKey`` fields take a number of extra arguments for defining how the
relationship should work. All are optional:

    =======================  ============================================================
    Argument                 Description
    =======================  ============================================================
    ``edit_inline``          If ``True``, this related object is edited
                             "inline" on the related object's page. This means
                             that the object will not have its own admin
                             interface. Use either ``models.TABULAR`` or ``models.STACKED``,
                             which, respectively, designate whether the inline-editable
                             objects are displayed as a table or as a "stack" of
                             fieldsets.

    ``limit_choices_to``     A dictionary of lookup arguments and values (see
                             the `Database API reference`_) that limit the
                             available admin choices for this object. Use this
                             with functions from the Python ``datetime`` module
                             to limit choices of objects by date. For example::

                                limit_choices_to = {'pub_date__lte': datetime.now}

                             only allows the choice of related objects with a
                             ``pub_date`` before the current date/time to be
                             chosen.

                             Instead of a dictionary this can also be a ``Q`` object
                             (an object with a ``get_sql()`` method) for more complex
                             queries.

                             Not compatible with ``edit_inline``.

    ``max_num_in_admin``     For inline-edited objects, this is the maximum
                             number of related objects to display in the admin.
                             Thus, if a pizza could only have up to 10
                             toppings, ``max_num_in_admin=10`` would ensure
                             that a user never enters more than 10 toppings.

                             Note that this doesn't ensure more than 10 related
                             toppings ever get created. It simply controls the
                             admin interface; it doesn't enforce things at the
                             Python API level or database level.

    ``min_num_in_admin``     The minimum number of related objects displayed in
                             the admin. Normally, at the creation stage,
                             ``num_in_admin`` inline objects are shown, and at
                             the edit stage ``num_extra_on_change`` blank
                             objects are shown in addition to all pre-existing
                             related objects.  However, no fewer than
                             ``min_num_in_admin`` related objects will ever be
                             displayed.

    ``num_extra_on_change``  The number of extra blank related-object fields to
                             show at the change stage.

    ``num_in_admin``         The default number of inline objects to display
                             on the object page at the add stage.

    ``raw_id_admin``         Only display a field for the integer to be entered
                             instead of a drop-down menu. This is useful when
                             related to an object type that will have too many
                             rows to make a select box practical.

                             Not used with ``edit_inline``.

    ``related_name``         The name to use for the relation from the related
                             object back to this one. See the
                             `related objects documentation`_ for a full
                             explanation and example.

                             If using this in an `abstract base class`_, be
                             sure to read the `extra notes`_ in that section
                             about ``related_name``.

    ``to_field``             The field on the related object that the relation
                             is to. By default, Django uses the primary key of
                             the related object.
    =======================  ============================================================

.. _`Database API reference`: ../db-api/
.. _related objects documentation: ../db-api/#related-objects
.. _abstract base class: `Abstract base classes`_
.. _extra notes: `Be careful with related_name`_

Many-to-many relationships
~~~~~~~~~~~~~~~~~~~~~~~~~~

To define a many-to-many relationship, use ``ManyToManyField``. You use it just
like any other ``Field`` type: by including it as a class attribute of your
model.

``ManyToManyField`` requires a positional argument: the class to which the
model is related.

For example, if a ``Pizza`` has multiple ``Topping`` objects -- that is, a
``Topping`` can be on multiple pizzas and each ``Pizza`` has multiple toppings --
here's how you'd represent that::

    class Topping(models.Model):
        # ...

    class Pizza(models.Model):
        # ...
        toppings = models.ManyToManyField(Topping)

As with ``ForeignKey``, a relationship to self can be defined by using the
string ``'self'`` instead of the model name, and you can refer to as-yet
undefined models by using a string containing the model name. However, you
can only use strings to refer to models in the same models.py file -- you
cannot use a string to reference a model in a different application, or to
reference a model that has been imported from elsewhere.

It's suggested, but not required, that the name of a ``ManyToManyField``
(``toppings`` in the example above) be a plural describing the set of related
model objects.

Behind the scenes, Django creates an intermediary join table to represent the
many-to-many relationship.

It doesn't matter which model gets the ``ManyToManyField``, but you only need
it in one of the models -- not in both.

Generally, ``ManyToManyField`` instances should go in the object that's going
to be edited in the admin interface, if you're using Django's admin. In the
above example, ``toppings`` is in ``Pizza`` (rather than ``Topping`` having a
``pizzas`` ``ManyToManyField`` ) because it's more natural to think about a
``Pizza`` having toppings than a topping being on multiple pizzas. The way it's
set up above, the ``Pizza`` admin form would let users select the toppings.

See the `Many-to-many relationship model example`_ for a full example.

.. _Many-to-many relationship model example: ../models/many_to_many/

``ManyToManyField`` objects take a number of extra arguments for defining how
the relationship should work. All are optional:

    =======================  ============================================================
    Argument                 Description
    =======================  ============================================================
    ``related_name``         See the description under ``ForeignKey`` above.

    ``filter_interface``     Use a nifty unobtrusive Javascript "filter" interface
                             instead of the usability-challenged ``<select multiple>``
                             in the admin form for this object. The value should be
                             ``models.HORIZONTAL`` or ``models.VERTICAL`` (i.e.
                             should the interface be stacked horizontally or
                             vertically).

    ``limit_choices_to``     See the description under ``ForeignKey`` above.

    ``symmetrical``          Only used in the definition of ManyToManyFields on self.
                             Consider the following model::

                                 class Person(models.Model):
                                     friends = models.ManyToManyField("self")

                             When Django processes this model, it identifies that it has
                             a ``ManyToManyField`` on itself, and as a result, it
                             doesn't add a ``person_set`` attribute to the ``Person``
                             class. Instead, the ``ManyToManyField`` is assumed to be
                             symmetrical -- that is, if I am your friend, then you are
                             my friend.

                             If you do not want symmetry in ``ManyToMany`` relationships
                             with ``self``, set ``symmetrical`` to ``False``. This will
                             force Django to add the descriptor for the reverse
                             relationship, allowing ``ManyToMany`` relationships to be
                             non-symmetrical.

    ``db_table``             The name of the table to create for storing the many-to-many
                             data. If this is not provided, Django will assume a default
                             name based upon the names of the two tables being joined.

    =======================  ============================================================

One-to-one relationships
~~~~~~~~~~~~~~~~~~~~~~~~

To define a one-to-one relationship, use ``OneToOneField``. You use it just
like any other ``Field`` type: by including it as a class attribute of your
model.

This is most useful on the primary key of an object when that object "extends"
another object in some way.

``OneToOneField`` requires a positional argument: the class to which the
model is related.

For example, if you're building a database of "places", you would build pretty
standard stuff such as address, phone number, etc. in the database. Then, if you
wanted to build a database of restaurants on top of the places, instead of
repeating yourself and replicating those fields in the ``Restaurant`` model, you
could make ``Restaurant`` have a ``OneToOneField`` to ``Place`` (because a
restaurant "is-a" place).

As with ``ForeignKey``, a relationship to self can be defined by using the
string ``"self"`` instead of the model name; references to as-yet undefined
models can be made by using a string containing the model name.

Finally, ``OneToOneField`` takes the following extra option:

    =======================  ============================================================
    Argument                 Description
    =======================  ============================================================
    ``parent_link``          When ``True`` and used in a model inherited from
                             another model, indicates that this field should
                             be used as the link from the child back to the
                             parent. See `Model inheritance`_ for more
                             details.

                             **New in Django development version**

    =======================  ============================================================

**New in Django development version:** ``OneToOneField`` classes used to
automatically become the primary key on a model. This is no longer true,
although you can manually pass in the ``primary_key`` attribute if you like.
Thus, it's now possible to have multiple fields of type ``OneToOneField`` on a
single model.

See the `One-to-one relationship model example`_ for a full example.

.. _One-to-one relationship model example: ../models/one_to_one/

Custom field types
------------------

**New in Django development version**

If one of the existing model fields cannot be used to fit your purposes, or if
you wish to take advantage of some less common database column types, you can
create your own field class. Full coverage of creating your own fields is
provided in the `Custom Model Fields`_ documentation.

.. _Custom Model Fields: ../custom_model_fields/

Meta options
============

Give your model metadata by using an inner ``class Meta``, like so::

    class Foo(models.Model):
        bar = models.CharField(max_length=30)

        class Meta:
            # ...

Model metadata is "anything that's not a field", such as ordering options, etc.

Here's a list of all possible ``Meta`` options. No options are required. Adding
``class Meta`` to a model is completely optional.

``abstract``
------------

**New in Django development version**

When set to ``True``, denotes this model as an abstract base class. See
`Abstract base classes`_ for more details. Defaults to ``False``.

``db_table``
------------

The name of the database table to use for the model::

    db_table = 'music_album'

If this isn't given, Django will use ``app_label + '_' + model_class_name``.
See "Table names" below for more.

If your database table name is an SQL reserved word, or contains characters
that aren't allowed in Python variable names -- notably, the hyphen --
that's OK. Django quotes column and table names behind the scenes.

``db_tablespace``
-----------------

**New in Django development version**

The name of the database tablespace to use for the model. If the backend
doesn't support tablespaces, this option is ignored.

``get_latest_by``
-----------------

The name of a ``DateField`` or ``DateTimeField`` in the model. This specifies
the default field to use in your model ``Manager``'s ``latest()`` method.

Example::

    get_latest_by = "order_date"

See the `docs for latest()`_ for more.

.. _docs for latest(): ../db-api/#latest-field-name-none

``order_with_respect_to``
-------------------------

Marks this object as "orderable" with respect to the given field. This is
almost always used with related objects to allow them to be ordered with
respect to a parent object. For example, if an ``Answer`` relates to a
``Question`` object, and a question has more than one answer, and the order
of answers matters, you'd do this::

    class Answer(models.Model):
        question = models.ForeignKey(Question)
        # ...

        class Meta:
            order_with_respect_to = 'question'

``ordering``
------------

The default ordering for the object, for use when obtaining lists of objects::

    ordering = ['-order_date']

This is a tuple or list of strings. Each string is a field name with an
optional "-" prefix, which indicates descending order. Fields without a
leading "-" will be ordered ascending. Use the string "?" to order randomly.

For example, to order by a ``pub_date`` field ascending, use this::

    ordering = ['pub_date']

To order by ``pub_date`` descending, use this::

    ordering = ['-pub_date']

To order by ``pub_date`` descending, then by ``author`` ascending, use this::

    ordering = ['-pub_date', 'author']

See `Specifying ordering`_ for more examples.

Note that, regardless of how many fields are in ``ordering``, the admin
site uses only the first field.

.. _Specifying ordering: ../models/ordering/

``permissions``
---------------

Extra permissions to enter into the permissions table when creating this
object. Add, delete and change permissions are automatically created for
each object that has ``admin`` set. This example specifies an extra
permission, ``can_deliver_pizzas``::

    permissions = (("can_deliver_pizzas", "Can deliver pizzas"),)

This is a list or tuple of 2-tuples in the format
``(permission_code, human_readable_permission_name)``.

``unique_together``
-------------------

Sets of field names that, taken together, must be unique::

    unique_together = (("driver", "restaurant"),)

This is a list of lists of fields that must be unique when considered
together. It's used in the Django admin and is enforced at the database
level (i.e., the appropriate ``UNIQUE`` statements are included in the
``CREATE TABLE`` statement).

All the fields specified in ``unique_together`` must be part of the current
model. If you are using `model inheritance`_, you cannot refer to fields from
any parent classes in ``unique_together``.

**New in Django development version**

For convenience, unique_together can be a single list when dealing
with a single set of fields::

	unique_together = ("driver", "restaurant")

``verbose_name``
----------------

A human-readable name for the object, singular::

    verbose_name = "pizza"

If this isn't given, Django will use a munged version of the class name:
``CamelCase`` becomes ``camel case``.

``verbose_name_plural``
-----------------------

The plural name for the object::

    verbose_name_plural = "stories"

If this isn't given, Django will use ``verbose_name + "s"``.

Table names
===========

To save you time, Django automatically derives the name of the database table
from the name of your model class and the app that contains it. A model's
database table name is constructed by joining the model's "app label" -- the
name you used in ``manage.py startapp`` -- to the model's class name, with an
underscore between them.

For example, if you have an app ``bookstore`` (as created by
``manage.py startapp bookstore``), a model defined as ``class Book`` will have
a database table named ``bookstore_book``.

To override the database table name, use the ``db_table`` parameter in
``class Meta``.

Automatic primary key fields
============================

By default, Django gives each model the following field::

    id = models.AutoField(primary_key=True)

This is an auto-incrementing primary key.

If you'd like to specify a custom primary key, just specify ``primary_key=True``
on one of your fields. If Django sees you've explicitly set ``primary_key``, it
won't add the automatic ``id`` column.

Each model requires exactly one field to have ``primary_key=True``.

The ``pk`` property
-------------------
**New in Django development version**

Regardless of whether you define a primary key field yourself, or let Django
supply one for you, each model will have a property called ``pk``. It behaves
like a normal attribute on the model, but is actually an alias for whichever
attribute is the primary key field for the model. You can read and set this
value, just as you would for any other attribute, and it will update the
correct field in the model.

Admin options
=============

If you want your model to be visible to Django's admin site, give your model an
inner ``"class Admin"``, like so::

    class Person(models.Model):
        first_name = models.CharField(max_length=30)
        last_name = models.CharField(max_length=30)

        class Admin:
            # Admin options go here
            pass

The ``Admin`` class tells Django how to display the model in the admin site.

Here's a list of all possible ``Admin`` options. None of these options are
required. To use an admin interface without specifying any options, use
``pass``, like so::

    class Admin:
        pass

Adding ``class Admin`` to a model is completely optional.

``date_hierarchy``
------------------

Set ``date_hierarchy`` to the name of a ``DateField`` or ``DateTimeField`` in
your model, and the change list page will include a date-based drilldown
navigation by that field.

Example::

    date_hierarchy = 'pub_date'

``fields``
----------

Set ``fields`` to control the layout of admin "add" and "change" pages.

``fields`` is a list of two-tuples, in which each two-tuple represents a
``<fieldset>`` on the admin form page. (A ``<fieldset>`` is a "section" of the
form.)

The two-tuples are in the format ``(name, field_options)``, where ``name`` is a
string representing the title of the fieldset and ``field_options`` is a
dictionary of information about the fieldset, including a list of fields to be
displayed in it.

A full example, taken from the ``django.contrib.flatpages.FlatPage`` model::

    class Admin:
        fields = (
            (None, {
                'fields': ('url', 'title', 'content', 'sites')
            }),
            ('Advanced options', {
                'classes': 'collapse',
                'fields' : ('enable_comments', 'registration_required', 'template_name')
            }),
        )

This results in an admin page that looks like:

    .. image:: http://media.djangoproject.com/img/doc/flatfiles_admin.png

If ``fields`` isn't given, Django will default to displaying each field that
isn't an ``AutoField`` and has ``editable=True``, in a single fieldset, in
the same order as the fields are defined in the model.

The ``field_options`` dictionary can have the following keys:

``fields``
~~~~~~~~~~

A tuple of field names to display in this fieldset. This key is required.

Example::

    {
    'fields': ('first_name', 'last_name', 'address', 'city', 'state'),
    }

To display multiple fields on the same line, wrap those fields in their own
tuple. In this example, the ``first_name`` and ``last_name`` fields will
display on the same line::

    {
    'fields': (('first_name', 'last_name'), 'address', 'city', 'state'),
    }

``classes``
~~~~~~~~~~~

A string containing extra CSS classes to apply to the fieldset.

Example::

    {
    'classes': 'wide',
    }

Apply multiple classes by separating them with spaces. Example::

    {
    'classes': 'wide extrapretty',
    }

Two useful classes defined by the default admin-site stylesheet are
``collapse`` and ``wide``. Fieldsets with the ``collapse`` style will be
initially collapsed in the admin and replaced with a small "click to expand"
link. Fieldsets with the ``wide`` style will be given extra horizontal space.

``description``
~~~~~~~~~~~~~~~

A string of optional extra text to be displayed at the top of each fieldset,
under the heading of the fieldset. It's used verbatim, so you can use any HTML
and you must escape any special HTML characters (such as ampersands) yourself.

``js``
------

A list of strings representing URLs of JavaScript files to link into the admin
screen via ``<script src="">`` tags. This can be used to tweak a given type of
admin page in JavaScript or to provide "quick links" to fill in default values
for certain fields.

If you use relative URLs -- URLs that don't start with ``http://`` or ``/`` --
then the admin site will automatically prefix these links with
``settings.ADMIN_MEDIA_PREFIX``.

``list_display``
----------------

Set ``list_display`` to control which fields are displayed on the change list
page of the admin.

Example::

    list_display = ('first_name', 'last_name')

If you don't set ``list_display``, the admin site will display a single column
that displays the ``__str__()`` representation of each object.

A few special cases to note about ``list_display``:

    * If the field is a ``ForeignKey``, Django will display the
      ``__unicode__()`` of the related object.

    * ``ManyToManyField`` fields aren't supported, because that would entail
      executing a separate SQL statement for each row in the table. If you
      want to do this nonetheless, give your model a custom method, and add
      that method's name to ``list_display``. (See below for more on custom
      methods in ``list_display``.)

    * If the field is a ``BooleanField`` or ``NullBooleanField``, Django will
      display a pretty "on" or "off" icon instead of ``True`` or ``False``.

    * If the string given is a method of the model, Django will call it and
      display the output. This method should have a ``short_description``
      function attribute, for use as the header for the field.

      Here's a full example model::

          class Person(models.Model):
              name = models.CharField(max_length=50)
              birthday = models.DateField()

              class Admin:
                  list_display = ('name', 'decade_born_in')

              def decade_born_in(self):
                  return self.birthday.strftime('%Y')[:3] + "0's"
              decade_born_in.short_description = 'Birth decade'

    * If the string given is a method of the model, Django will HTML-escape the
      output by default. If you'd rather not escape the output of the method,
      give the method an ``allow_tags`` attribute whose value is ``True``.

      Here's a full example model::

          class Person(models.Model):
              first_name = models.CharField(max_length=50)
              last_name = models.CharField(max_length=50)
              color_code = models.CharField(max_length=6)

              class Admin:
                  list_display = ('first_name', 'last_name', 'colored_name')

              def colored_name(self):
                  return '<span style="color: #%s;">%s %s</span>' % (self.color_code, self.first_name, self.last_name)
              colored_name.allow_tags = True

    * If the string given is a method of the model that returns True or False
      Django will display a pretty "on" or "off" icon if you give the method a
      ``boolean`` attribute whose value is ``True``.

      Here's a full example model::

          class Person(models.Model):
              first_name = models.CharField(max_length=50)
              birthday = models.DateField()

              class Admin:
                  list_display = ('name', 'born_in_fifties')

              def born_in_fifties(self):
                  return self.birthday.strftime('%Y')[:3] == 5
              born_in_fifties.boolean = True


    * The ``__str__()`` and ``__unicode__()`` methods are just as valid in
      ``list_display`` as any other model method, so it's perfectly OK to do
      this::

          list_display = ('__unicode__', 'some_other_field')

    * Usually, elements of ``list_display`` that aren't actual database fields
      can't be used in sorting (because Django does all the sorting at the
      database level).

      However, if an element of ``list_display`` represents a certain database
      field, you can indicate this fact by setting the ``admin_order_field``
      attribute of the item.

      For example::

        class Person(models.Model):
            first_name = models.CharField(max_length=50)
            color_code = models.CharField(max_length=6)

            class Admin:
                list_display = ('first_name', 'colored_first_name')

            def colored_first_name(self):
                return '<span style="color: #%s;">%s</span>' % (self.color_code, self.first_name)
            colored_first_name.allow_tags = True
            colored_first_name.admin_order_field = 'first_name'

      The above will tell Django to order by the ``first_name`` field when
      trying to sort by ``colored_first_name`` in the admin.

``list_display_links``
----------------------

Set ``list_display_links`` to control which fields in ``list_display`` should
be linked to the "change" page for an object.

By default, the change list page will link the first column -- the first field
specified in ``list_display`` -- to the change page for each item. But
``list_display_links`` lets you change which columns are linked. Set
``list_display_links`` to a list or tuple of field names (in the same format as
``list_display``) to link.

``list_display_links`` can specify one or many field names. As long as the
field names appear in ``list_display``, Django doesn't care how many (or how
few) fields are linked. The only requirement is: If you want to use
``list_display_links``, you must define ``list_display``.

In this example, the ``first_name`` and ``last_name`` fields will be linked on
the change list page::

    class Admin:
        list_display = ('first_name', 'last_name', 'birthday')
        list_display_links = ('first_name', 'last_name')

Finally, note that in order to use ``list_display_links``, you must define
``list_display``, too.

``list_filter``
---------------

Set ``list_filter`` to activate filters in the right sidebar of the change list
page of the admin. This should be a list of field names, and each specified
field should be either a ``BooleanField``, ``CharField``, ``DateField``,
``DateTimeField``, ``IntegerField`` or ``ForeignKey``.

This example, taken from the ``django.contrib.auth.models.User`` model, shows
how both ``list_display`` and ``list_filter`` work::

    class Admin:
        list_display = ('username', 'email', 'first_name', 'last_name', 'is_staff')
        list_filter = ('is_staff', 'is_superuser')

The above code results in an admin change list page that looks like this:

    .. image:: http://media.djangoproject.com/img/doc/users_changelist.png

(This example also has ``search_fields`` defined. See below.)

``list_per_page``
-----------------

Set ``list_per_page`` to control how many items appear on each paginated admin
change list page. By default, this is set to ``100``.

``list_select_related``
-----------------------

Set ``list_select_related`` to tell Django to use ``select_related()`` in
retrieving the list of objects on the admin change list page. This can save you
a bunch of database queries.

The value should be either ``True`` or ``False``. Default is ``False``.

Note that Django will use ``select_related()``, regardless of this setting,
if one of the ``list_display`` fields is a ``ForeignKey``.

For more on ``select_related()``, see `the select_related() docs`_.

.. _the select_related() docs: ../db-api/#select-related

``ordering``
------------

Set ``ordering`` to specify how objects on the admin change list page should be
ordered. This should be a list or tuple in the same format as a model's
``ordering`` parameter.

If this isn't provided, the Django admin will use the model's default ordering.

``save_as``
-----------

Set ``save_as`` to enable a "save as" feature on admin change forms.

Normally, objects have three save options: "Save", "Save and continue editing"
and "Save and add another". If ``save_as`` is ``True``, "Save and add another"
will be replaced by a "Save as" button.

"Save as" means the object will be saved as a new object (with a new ID),
rather than the old object.

By default, ``save_as`` is set to ``False``.

``save_on_top``
---------------

Set ``save_on_top`` to add save buttons across the top of your admin change
forms.

Normally, the save buttons appear only at the bottom of the forms. If you set
``save_on_top``, the buttons will appear both on the top and the bottom.

By default, ``save_on_top`` is set to ``False``.

``search_fields``
-----------------

Set ``search_fields`` to enable a search box on the admin change list page.
This should be set to a list of field names that will be searched whenever
somebody submits a search query in that text box.

These fields should be some kind of text field, such as ``CharField`` or
``TextField``. You can also perform a related lookup on a ``ForeignKey`` with
the lookup API "follow" notation::

    search_fields = ['foreign_key__related_fieldname']

When somebody does a search in the admin search box, Django splits the search
query into words and returns all objects that contain each of the words, case
insensitive, where each word must be in at least one of ``search_fields``. For
example, if ``search_fields`` is set to ``['first_name', 'last_name']`` and a
user searches for ``john lennon``, Django will do the equivalent of this SQL
``WHERE`` clause::

    WHERE (first_name ILIKE '%john%' OR last_name ILIKE '%john%')
    AND (first_name ILIKE '%lennon%' OR last_name ILIKE '%lennon%')

For faster and/or more restrictive searches, prefix the field name
with an operator:

``^``
    Matches the beginning of the field. For example, if ``search_fields`` is
    set to ``['^first_name', '^last_name']`` and a user searches for
    ``john lennon``, Django will do the equivalent of this SQL ``WHERE``
    clause::

        WHERE (first_name ILIKE 'john%' OR last_name ILIKE 'john%')
        AND (first_name ILIKE 'lennon%' OR last_name ILIKE 'lennon%')

    This query is more efficient than the normal ``'%john%'`` query, because
    the database only needs to check the beginning of a column's data, rather
    than seeking through the entire column's data. Plus, if the column has an
    index on it, some databases may be able to use the index for this query,
    even though it's a ``LIKE`` query.

``=``
    Matches exactly, case-insensitive. For example, if
    ``search_fields`` is set to ``['=first_name', '=last_name']`` and
    a user searches for ``john lennon``, Django will do the equivalent
    of this SQL ``WHERE`` clause::

        WHERE (first_name ILIKE 'john' OR last_name ILIKE 'john')
        AND (first_name ILIKE 'lennon' OR last_name ILIKE 'lennon')

    Note that the query input is split by spaces, so, following this example,
    it's currently not possible to search for all records in which
    ``first_name`` is exactly ``'john winston'`` (containing a space).

``@``
    Performs a full-text match. This is like the default search method but uses
    an index. Currently this is only available for MySQL.

Managers
========

A ``Manager`` is the interface through which database query operations are
provided to Django models. At least one ``Manager`` exists for every model in
a Django application.

The way ``Manager`` classes work is documented in the `Retrieving objects`_
section of the database API docs, but this section specifically touches on
model options that customize ``Manager`` behavior.

.. _Retrieving objects: ../db-api/#retrieving-objects

Manager names
-------------

By default, Django adds a ``Manager`` with the name ``objects`` to every Django
model class. However, if you want to use ``objects`` as a field name, or if you
want to use a name other than ``objects`` for the ``Manager``, you can rename
it on a per-model basis. To rename the ``Manager`` for a given class, define a
class attribute of type ``models.Manager()`` on that model. For example::

    from django.db import models

    class Person(models.Model):
        #...
        people = models.Manager()

Using this example model, ``Person.objects`` will generate an
``AttributeError`` exception, but ``Person.people.all()`` will provide a list
of all ``Person`` objects.

Custom Managers
---------------

You can use a custom ``Manager`` in a particular model by extending the base
``Manager`` class and instantiating your custom ``Manager`` in your model.

There are two reasons you might want to customize a ``Manager``: to add extra
``Manager`` methods, and/or to modify the initial ``QuerySet`` the ``Manager``
returns.

Adding extra Manager methods
~~~~~~~~~~~~~~~~~~~~~~~~~~~~

Adding extra ``Manager`` methods is the preferred way to add "table-level"
functionality to your models. (For "row-level" functionality -- i.e., functions
that act on a single instance of a model object -- use `Model methods`_, not
custom ``Manager`` methods.)

A custom ``Manager`` method can return anything you want. It doesn't have to
return a ``QuerySet``.

For example, this custom ``Manager`` offers a method ``with_counts()``, which
returns a list of all ``OpinionPoll`` objects, each with an extra
``num_responses`` attribute that is the result of an aggregate query::

    class PollManager(models.Manager):
        def with_counts(self):
            from django.db import connection
            cursor = connection.cursor()
            cursor.execute("""
                SELECT p.id, p.question, p.poll_date, COUNT(*)
                FROM polls_opinionpoll p, polls_response r
                WHERE p.id = r.poll_id
                GROUP BY 1, 2, 3
                ORDER BY 3 DESC""")
            result_list = []
            for row in cursor.fetchall():
                p = self.model(id=row[0], question=row[1], poll_date=row[2])
                p.num_responses = row[3]
                result_list.append(p)
            return result_list

    class OpinionPoll(models.Model):
        question = models.CharField(max_length=200)
        poll_date = models.DateField()
        objects = PollManager()

    class Response(models.Model):
        poll = models.ForeignKey(Poll)
        person_name = models.CharField(max_length=50)
        response = models.TextField()

With this example, you'd use ``OpinionPoll.objects.with_counts()`` to return
that list of ``OpinionPoll`` objects with ``num_responses`` attributes.

Another thing to note about this example is that ``Manager`` methods can
access ``self.model`` to get the model class to which they're attached.

Modifying initial Manager QuerySets
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

A ``Manager``'s base ``QuerySet`` returns all objects in the system. For
example, using this model::

    class Book(models.Model):
        title = models.CharField(max_length=100)
        author = models.CharField(max_length=50)

...the statement ``Book.objects.all()`` will return all books in the database.

You can override a ``Manager``\'s base ``QuerySet`` by overriding the
``Manager.get_query_set()`` method. ``get_query_set()`` should return a
``QuerySet`` with the properties you require.

For example, the following model has *two* ``Manager``\s -- one that returns
all objects, and one that returns only the books by Roald Dahl::

    # First, define the Manager subclass.
    class DahlBookManager(models.Manager):
        def get_query_set(self):
            return super(DahlBookManager, self).get_query_set().filter(author='Roald Dahl')

    # Then hook it into the Book model explicitly.
    class Book(models.Model):
        title = models.CharField(max_length=100)
        author = models.CharField(max_length=50)

        objects = models.Manager() # The default manager.
        dahl_objects = DahlBookManager() # The Dahl-specific manager.

With this sample model, ``Book.objects.all()`` will return all books in the
database, but ``Book.dahl_objects.all()`` will only return the ones written by
Roald Dahl.

Of course, because ``get_query_set()`` returns a ``QuerySet`` object, you can
use ``filter()``, ``exclude()`` and all the other ``QuerySet`` methods on it.
So these statements are all legal::

    Book.dahl_objects.all()
    Book.dahl_objects.filter(title='Matilda')
    Book.dahl_objects.count()

This example also pointed out another interesting technique: using multiple
managers on the same model. You can attach as many ``Manager()`` instances to
a model as you'd like. This is an easy way to define common "filters" for your
models.

For example::

    class MaleManager(models.Manager):
        def get_query_set(self):
            return super(MaleManager, self).get_query_set().filter(sex='M')

    class FemaleManager(models.Manager):
        def get_query_set(self):
            return super(FemaleManager, self).get_query_set().filter(sex='F')

    class Person(models.Model):
        first_name = models.CharField(max_length=50)
        last_name = models.CharField(max_length=50)
        sex = models.CharField(max_length=1, choices=(('M', 'Male'), ('F', 'Female')))
        people = models.Manager()
        men = MaleManager()
        women = FemaleManager()

This example allows you to request ``Person.men.all()``, ``Person.women.all()``,
and ``Person.people.all()``, yielding predictable results.

If you use custom ``Manager`` objects, take note that the first
``Manager`` Django encounters (in the order in which they're defined
in the model) has a special status. Django interprets this first
``Manager`` defined in a class as the "default" ``Manager``, and
several parts of Django (though not the admin application) will use
that ``Manager`` exclusively for that model. As a result, it's often a
good idea to be careful in your choice of default manager, in order to
avoid a situation where overriding of ``get_query_set()`` results in
an inability to retrieve objects you'd like to work with.

Model methods
=============

Define custom methods on a model to add custom "row-level" functionality to
your objects. Whereas ``Manager`` methods are intended to do "table-wide"
things, model methods should act on a particular model instance.

This is a valuable technique for keeping business logic in one place -- the
model.

For example, this model has a few custom methods::

    class Person(models.Model):
        first_name = models.CharField(max_length=50)
        last_name = models.CharField(max_length=50)
        birth_date = models.DateField()
        address = models.CharField(max_length=100)
        city = models.CharField(max_length=50)
        state = models.USStateField() # Yes, this is America-centric...

        def baby_boomer_status(self):
            "Returns the person's baby-boomer status."
            import datetime
            if datetime.date(1945, 8, 1) <= self.birth_date <= datetime.date(1964, 12, 31):
                return "Baby boomer"
            if self.birth_date < datetime.date(1945, 8, 1):
                return "Pre-boomer"
            return "Post-boomer"

        def is_midwestern(self):
            "Returns True if this person is from the Midwest."
            return self.state in ('IL', 'WI', 'MI', 'IN', 'OH', 'IA', 'MO')

        def _get_full_name(self):
            "Returns the person's full name."
            return '%s %s' % (self.first_name, self.last_name)
        full_name = property(_get_full_name)

The last method in this example is a *property*. `Read more about properties`_.

.. _Read more about properties: http://www.python.org/download/releases/2.2/descrintro/#property

A few object methods have special meaning:

``__str__``
-----------

``__str__()`` is a Python "magic method" that defines what should be returned
if you call ``str()`` on the object. Django uses ``str(obj)`` (or the related
function, ``unicode(obj)`` -- see below) in a number of places, most notably
as the value displayed to render an object in the Django admin site and as the
value inserted into a template when it displays an object. Thus, you should
always return a nice, human-readable string for the object's ``__str__``.
Although this isn't required, it's strongly encouraged (see the description of
``__unicode__``, below, before putting ``__str__`` methods everywhere).

For example::

    class Person(models.Model):
        first_name = models.CharField(max_length=50)
        last_name = models.CharField(max_length=50)

        def __str__(self):
            # Note use of django.utils.encoding.smart_str() here because
            # first_name and last_name will be unicode strings.
            return smart_str('%s %s' % (self.first_name, self.last_name))

``__unicode__``
---------------

The ``__unicode__()`` method is called whenever you call ``unicode()`` on an
object. Since Django's database backends will return Unicode strings in your
model's attributes, you would normally want to write a ``__unicode__()``
method for your model. The example in the previous section could be written
more simply as::

    class Person(models.Model):
        first_name = models.CharField(max_length=50)
        last_name = models.CharField(max_length=50)

        def __unicode__(self):
            return u'%s %s' % (self.first_name, self.last_name)

If you define a ``__unicode__()`` method on your model and not a ``__str__()``
method, Django will automatically provide you with a ``__str__()`` that calls
``__unicode__()`` and then converts the result correctly to a UTF-8 encoded
string object. This is recommended development practice: define only
``__unicode__()`` and let Django take care of the conversion to string objects
when required.

``get_absolute_url``
--------------------

Define a ``get_absolute_url()`` method to tell Django how to calculate the
URL for an object. For example::

    def get_absolute_url(self):
        return "/people/%i/" % self.id

Django uses this in its admin interface. If an object defines
``get_absolute_url()``, the object-editing page will have a "View on site"
link that will jump you directly to the object's public view, according to
``get_absolute_url()``.

Also, a couple of other bits of Django, such as the `syndication feed framework`_,
use ``get_absolute_url()`` as a convenience to reward people who've defined the
method.

.. _syndication feed framework: ../syndication_feeds/

It's good practice to use ``get_absolute_url()`` in templates, instead of
hard-coding your objects' URLs. For example, this template code is bad::

    <a href="/people/{{ object.id }}/">{{ object.name }}</a>

But this template code is good::

    <a href="{{ object.get_absolute_url }}">{{ object.name }}</a>

.. note::
    The string you return from ``get_absolute_url()`` must contain only ASCII
    characters (required by the URI spec, `RFC 2396`_) that have been
    URL-encoded, if necessary. Code and templates using ``get_absolute_url()``
    should be able to use the result directly without needing to do any
    further processing. You may wish to use the
    ``django.utils.encoding.iri_to_uri()`` function to help with this if you
    are using unicode strings a lot.

.. _RFC 2396: http://www.ietf.org/rfc/rfc2396.txt

The ``permalink`` decorator
~~~~~~~~~~~~~~~~~~~~~~~~~~~

The problem with the way we wrote ``get_absolute_url()`` above is that it
slightly violates the DRY principle: the URL for this object is defined both
in the URLConf file and in the model.

You can further decouple your models from the URLconf using the ``permalink``
decorator. This decorator is passed the view function, a list of positional
parameters and (optionally) a dictionary of named parameters. Django then
works out the correct full URL path using the URLconf, substituting the
parameters you have given into the URL. For example, if your URLconf
contained a line such as::

    (r'^people/(\d+)/$', 'people.views.details'),

...your model could have a ``get_absolute_url`` method that looked like this::

    from django.db.models import permalink

    def get_absolute_url(self):
        return ('people.views.details', [str(self.id)])
    get_absolute_url = permalink(get_absolute_url)

Similarly, if you had a URLconf entry that looked like::

    (r'/archive/(?P<year>\d{4})/(?P<month>\d{1,2})/(?P<day>\d{1,2})/$', archive_view)

...you could reference this using ``permalink()`` as follows::

    def get_absolute_url(self):
        return ('archive_view', (), {
            'year': self.created.year,
            'month': self.created.month,
            'day': self.created.day})
    get_absolute_url = permalink(get_absolute_url)

Notice that we specify an empty sequence for the second parameter in this case,
because we only want to pass keyword parameters, not positional ones.

In this way, you're tying the model's absolute URL to the view that is used
to display it, without repeating the URL information anywhere. You can still
use the ``get_absolute_url`` method in templates, as before.

In some cases, such as the use of generic views or the re-use of
custom views for multiple models, specifying the view function may
confuse the reverse URL matcher (because multiple patterns point to
the same view).

For that problem, Django has **named URL patterns**. Using a named
URL pattern, it's possible to give a name to a pattern, and then
reference the name rather than the view function. A named URL
pattern is defined by replacing the pattern tuple by a call to
the ``url`` function)::

    from django.conf.urls.defaults import *

    url(r'^people/(\d+)/$',
        'django.views.generic.list_detail.object_detail',
        name='people_view'),

...and then using that name to perform the reverse URL resolution instead
of the view name::

    from django.db.models import permalink

    def get_absolute_url(self):
        return ('people_view', [str(self.id)])
    get_absolute_url = permalink(get_absolute_url)

More details on named URL patterns are in the `URL dispatch documentation`_.

.. _URL dispatch documentation: ../url_dispatch/#naming-url-patterns

Executing custom SQL
--------------------

Feel free to write custom SQL statements in custom model methods and
module-level methods. The object ``django.db.connection`` represents the
current database connection. To use it, call ``connection.cursor()`` to get a
cursor object. Then, call ``cursor.execute(sql, [params])`` to execute the SQL
and ``cursor.fetchone()`` or ``cursor.fetchall()`` to return the resulting
rows. Example::

    def my_custom_sql(self):
        from django.db import connection
        cursor = connection.cursor()
        cursor.execute("SELECT foo FROM bar WHERE baz = %s", [self.baz])
        row = cursor.fetchone()
        return row

``connection`` and ``cursor`` mostly implement the standard `Python DB-API`_
(except when it comes to `transaction handling`_). If you're not familiar with
the Python DB-API, note that the SQL statement in ``cursor.execute()`` uses
placeholders, ``"%s"``, rather than adding parameters directly within the SQL.
If you use this technique, the underlying database library will automatically
add quotes and escaping to your parameter(s) as necessary. (Also note that
Django expects the ``"%s"`` placeholder, *not* the ``"?"`` placeholder, which is
used by the SQLite Python bindings. This is for the sake of consistency and
sanity.)

A final note: If all you want to do is a custom ``WHERE`` clause, you can just
use the ``where``, ``tables`` and ``params`` arguments to the standard lookup
API. See `Other lookup options`_.

.. _Python DB-API: http://www.python.org/peps/pep-0249.html
.. _Other lookup options: ../db-api/#extra-select-none-where-none-params-none-tables-none
.. _transaction handling: ../transactions/

Overriding default model methods
--------------------------------

As explained in the `database API docs`_, each model gets a few methods
automatically -- most notably, ``save()`` and ``delete()``. You can override
these methods to alter behavior.

A classic use-case for overriding the built-in methods is if you want something
to happen whenever you save an object. For example::

    class Blog(models.Model):
        name = models.CharField(max_length=100)
        tagline = models.TextField()

        def save(self):
            do_something()
            super(Blog, self).save() # Call the "real" save() method.
            do_something_else()

You can also prevent saving::

    class Blog(models.Model):
        name = models.CharField(max_length=100)
        tagline = models.TextField()

        def save(self):
            if self.name == "Yoko Ono's blog":
                return # Yoko shall never have her own blog!
            else:
                super(Blog, self).save() # Call the "real" save() method.

.. _database API docs: ../db-api/

Model inheritance
=================

**New in Django development version**

Model inheritance in Django works almost identically to the way normal class
inheritance works in Python. The only decision you have to make is whether you
want the parent models to be models in their own right (with their own
database tables), or if the parents are just holders of common information
that will only be visible through the child models.

Often, you will just want to use the parent class to hold information that you
don't want to have to type out for each child model. This class isn't going to
ever be used in isolation, so `abstract base classes`_ are what you're after. However, if you're subclassing an existing model (perhaps something from another application entirely), or want each model to have its own database table, `multi-table inheritance`_ is the way to go.

Abstract base classes
---------------------

Abstract base classes are useful when you want to put some common information
into a number of other models. You write your base class and put
``abstract=True`` in the ``Meta`` class. This model will then not be used to
create any database table. Instead, when it is used as a base class for other
models, its fields will be added to those of the child class. It is an error
to have fields in the abstract base class with the same name as those in the
child (and Django will raise an exception).

An example::

    class CommonInfo(models.Model):
        name = models.CharField(max_length=100)
        age = models.PositiveIntegerField()

        class Meta:
            abstract = True

    class Student(CommonInfo):
        home_group = models.CharField(max_length=5)

The ``Student`` model will have three fields: ``name``, ``age`` and
``home_group``. The ``CommonInfo`` model cannot be used as a normal Django
model, since it is an abstract base class. It does not generate a database
table or have a manager or anything like that.

For many uses, this type of model inheritance will be exactly what you want.
It provides a way to factor out common information at the Python level, whilst
still only creating one database table per child model at the database level.

``Meta`` inheritance
~~~~~~~~~~~~~~~~~~~~

When an abstract base class is created, Django makes any ``Meta`` inner class
you declared on the base class available as an attribute. If a child class
does not declare its own ``Meta`` class, it will inherit the parent's
``Meta``. If the child wants to extend the parent's ``Meta`` class, it can
subclass it. For example::

    class CommonInfo(models.Model):
        ...
        class Meta:
            abstract = True
            ordering = ['name']

    class Student(CommonInfo):
        ...
        class Meta(CommonInfo.Meta):
            db_table = 'student_info'

Django does make one adjustment to the ``Meta`` class of an abstract base
class: before installing the ``Meta`` attribute, it sets ``abstract=False``.
This means that children of abstract base classes don't automatically become
abstract classes themselves. Of course, you can make an abstract base class
that inherits from another abstract base class. You just need to remember to
explicitly set ``abstract=True`` each time.

Some attributes won't make sense to include in the ``Meta`` class of an
abstract base class. For example, including ``db_table`` would mean that all
the child classes (the ones that don't specify their own ``Meta``) would use
the same database table, which is almost certainly not what you want.

Be careful with ``related_name``
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

If you are using the ``related_name`` attribute on a ``ForeignKey`` or
``ManyToManyField``, you must always specify a *unique* reverse name for the
field. This would normally cause a problem in abstract base classes, since the
fields on this class are included into each of the child classes, with exactly
the same values for the attributes (including ``related_name``) each time.

To work around this problem, when you are using ``related_name`` in an
abstract base class (only), part of the name should be the string
``'%(class)s'``. This is replaced by the lower-cased name of the child class
that the field is used in. Since each class has a different name, each related
name will end up being different. For example::

    class Base(models.Model):
        m2m = models.ManyToMany(OtherModel, related_name="%(class)s_related")

        class Meta:
            abstract = True

    class ChildA(Base):
        pass

    class ChildB(Base):
        pass

The reverse name of the ``ChildA.m2m`` field will be ``childa_related``,
whilst the reverse name of the ``ChildB.m2m`` field will be
``childb_related``. It is up to you how you use the ``'%(class)s'`` portion to
construct your related name, but if you forget to use it, Django will raise
errors when you validate your models (or run ``syncdb``).

If you don't specify a ``related_name`` attribute for a field in an abstract
base class, the default reverse name will be the name of the child class
followed by ``'_set'``, just as it normally would be if you'd declared the field directly on the child class. For example, in the above code, if the ``related_name`` attribute was omitted, the reverse name for the ``m2m`` field would be ``childa_set`` in the ``ChildA`` case and ``childb_set`` for the ``ChildB`` field.

Multi-table inheritance
-----------------------

The second type of model inheritance supported by Django is when each model in
the hierarchy is a model all by itself. Each model corresponds to its own
database table and can be queried and created individually. The inheritance
relationship introduces links between the child model and each of its parents
(via an automatically created ``OneToOneField``). For example::

    class Place(models.Model):
        name = models.CharField(max_length=50)
        address = models.CharField(max_length=80)

    class Restaurant(Place):
        serves_hot_dogs = models.BooleanField()
        serves_pizza = models.BooleanField()

All of the fields of ``Place`` will also be available in ``Restaurant``,
although the data will reside in a different database table. So these are both
possible::

    >>> Place.objects.filter(name="Bob's Cafe")
    >>> Restaurant.objects.filter(name="Bob's Cafe")

If you have a ``Place`` that is also a ``Restaurant``, you can get from the
``Place`` object to the ``Restaurant`` object by using the lower-case version
of the model name::

    >>> p = Place.objects.filter(name="Bob's Cafe")
    # If Bob's Cafe is a Restaurant object, this will give the child class:
    >>> p.restaurant
    <Restaurant: ...>

However, if ``p`` in the above example was *not* a ``Restaurant`` (it had been
created directly as a ``Place`` object or was the parent of some other class),
referring to ``p.restaurant`` would give an error.

``Meta`` and multi-table inheritance
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

In the multi-table inheritance situation, it doesn't make sense for a child
class to inherit from its parent's ``Meta`` class. All the ``Meta`` options
have already been applied to the parent class and applying them again would
normally only lead to contradictory behaviour (this is in contrast with the
abstract base class case, where the base class doesn't exist in its own
right).

So a child model does not have access to its parent's ``Meta`` class. However,
there are a few limited cases where the child inherits behaviour from the
parent: if the child does not specify an ``ordering`` attribute or a
``get_latest_by`` attribute, it will inherit these from its parent.

If the parent has an ordering and you don't want the child to have any natural
ordering, you can explicitly set it to be empty::

    class ChildModel(ParentModel):
        ...
        class Meta:
            # Remove parent's ordering effect
            ordering = []

Inheritance and reverse relations
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

Because multi-table inheritance uses an implicit ``OneToOneField`` to link the
child and the parent, it's possible to move from the parent down to the child,
as in the above example. However, this uses up the name that is the default
``related_name`` value for ``ForeignKey`` and ``ManyToManyField`` relations.
If you are putting those type of relations on a subclass of another model, you
**must** specify the ``related_name`` attribute on each such field. If you
forget, Django will raise an error when you run ``manage.py validate`` or try
to syncdb.

For example, using the above ``Place`` class again, let's create another
subclass with a ``ManyToManyField``::

    class Supplier(Place):
        # Must specify related_name on all relations.
        customers = models.ManyToManyField(Restaurant,
                related_name='provider')

For more information about reverse relations, refer to the `Database API
reference`_ . For now, just remember to run ``manage.py validate`` when
you're writing your models and pay attention to the error messages.

Specifying the parent link field
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

As mentioned, Django will automatically create a ``OneToOneField`` linking
your child class back any non-abstract parent models. If you want to control
the name of the attribute linking back to the parent, you can create your own
link field and pass it ``parent_link=True``. For example, to explicitly
specify the field that will link ``Supplier`` to ``Place`` in the above
example, you could write::

    class Supplier(Place):
        parent = models.OneToOneField(Place, parent_link=True)
        ...

Multiple inheritance
--------------------

Just as with Python's subclassing, it's possible for a Django model to inherit
from multiple parent models. Keep in mind that normal Python name resolution
rules apply. The first base class that a particular name appears in (e.g.
``Meta``) will be the one that is used. We stop searching once we find the
name once. This means that if multiple parents contain a ``Meta`` class, only
the first one is going to be used. All others will be ignored.

Generally, you won't need to inherit from multiple parents. The main use-case
where this is useful is for ''mix-in'' classes: adding a particular extra
field or method to every class that inherits the mix-in. Try to keep your
inheritance hierarchies as simple and straightforward as possible so that you
won't have to struggle to work out where a particular piece of information is
coming from.

Models across files
===================

It's perfectly OK to relate a model to one from another app. To do this, just
import the related model at the top of the model that holds your model. Then,
just refer to the other model class wherever needed. For example::

    from mysite.geography.models import ZipCode

    class Restaurant(models.Model):
        # ...
        zip_code = models.ForeignKey(ZipCode)

Using models
============

Once you have created your models, the final step is to tell Django you're
going to *use* those models.

Do this by editing your settings file and changing the ``INSTALLED_APPS``
setting to add the name of the module that contains your ``models.py``.

For example, if the models for your application live in the module
``mysite.myapp.models`` (the package structure that is created for an
application by the ``manage.py startapp`` script), ``INSTALLED_APPS`` should
read, in part::

    INSTALLED_APPS = (
        #...
        'mysite.myapp',
        #...
    )

Providing initial SQL data
==========================

Django provides a hook for passing the database arbitrary SQL that's executed
just after the CREATE TABLE statements. Use this hook, for example, if you want
to populate default records, or create SQL functions, automatically.

The hook is simple: Django just looks for a file called
``<appname>/sql/<modelname>.sql``, where ``<appname>`` is your app directory and
``<modelname>`` is the model's name in lowercase.

In the ``Person`` example model at the top of this document, assuming it lives
in an app called ``myapp``, you could add arbitrary SQL to the file
``myapp/sql/person.sql``. Here's an example of what the file might contain::

    INSERT INTO myapp_person (first_name, last_name) VALUES ('John', 'Lennon');
    INSERT INTO myapp_person (first_name, last_name) VALUES ('Paul', 'McCartney');

Each SQL file, if given, is expected to contain valid SQL. The SQL files are
piped directly into the database after all of the models' table-creation
statements have been executed.

The SQL files are read by the ``sqlcustom``, ``sqlreset``, ``sqlall`` and
``reset`` commands in ``manage.py``. Refer to the `manage.py documentation`_
for more information.

Note that if you have multiple SQL data files, there's no guarantee of the
order in which they're executed. The only thing you can assume is that, by the
time your custom data files are executed, all the database tables already will
have been created.

.. _`manage.py documentation`: ../django-admin/#sqlcustom-appname-appname

Database-backend-specific SQL data
----------------------------------

There's also a hook for backend-specific SQL data. For example, you can have
separate initial-data files for PostgreSQL and MySQL. For each app, Django
looks for a file called ``<appname>/sql/<modelname>.<backend>.sql``, where
``<appname>`` is your app directory, ``<modelname>`` is the model's name in
lowercase and ``<backend>`` is the value of ``DATABASE_ENGINE`` in your
settings file (e.g., ``postgresql``, ``mysql``).

Backend-specific SQL data is executed before non-backend-specific SQL data. For
example, if your app contains the files ``sql/person.sql`` and
``sql/person.postgresql.sql`` and you're installing the app on PostgreSQL,
Django will execute the contents of ``sql/person.postgresql.sql`` first, then
``sql/person.sql``.